/*=========================================================================

  Program:   Visualization Toolkit
  Module:    vtkIncrementalOctreeNode.h

  Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen
  All rights reserved.
  See Copyright.txt or http://www.kitware.com/Copyright.htm for details.

     This software is distributed WITHOUT ANY WARRANTY; without even
     the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
     PURPOSE.  See the above copyright notice for more information.
 
=========================================================================*/
// .NAME vtkIncrementalOctreeNode - Octree node constituting incremental
//  octree (in support of both point location and point insertion)
//
// .SECTION Description
//  Octree nodes serve as spatial sub-division primitives to build the search
//  structure of an incremental octree in a recursive top-down manner. The
//  hierarchy takes the form of a tree-like representation by which a parent
//  node contains eight mutually non-overlapping child nodes. Each child is 
//  assigned with an axis-aligned rectangular volume (Spatial Bounding Box) 
//  and the eight children together cover exactly the same region as governed
//  by their parent. The eight child nodes / octants are ordered as
//
//  { (xBBoxMin, xBBoxMid] & (yBBoxMin, yBBoxMid] & (zBBoxMin, zBBoxMid] },
//  { (xBBoxMid, xBBoxMax] & (yBBoxMin, yBBoxMid] & (zBBoxMin, zBBoxMid] },
//  { (xBBoxMin, xBBoxMid] & (yBBoxMid, yBBoxMax] & (zBBoxMin, zBBoxMid] }, 
//  { (xBBoxMid, xBBoxMax] & (yBBoxMid, yBBoxMax] & (zBBoxMin, zBBoxMid] },
//  { (xBBoxMin, xBBoxMid] & (yBBoxMin, yBBoxMid] & (zBBoxMid, zBBoxMax] },
//  { (xBBoxMid, xBBoxMax] & (yBBoxMin, yBBoxMid] & (zBBoxMid, zBBoxMax] },
//  { (xBBoxMin, xBBoxMid] & (yBBoxMid, yBBoxMax] & (zBBoxMid, zBBoxMax] }, 
//  { (xBBoxMid, xBBoxMax] & (yBBoxMid, yBBoxMax] & (zBBoxMid, zBBoxMax] },
//
//  where { xrange & yRange & zRange } defines the region of each 3D octant. 
//  In addition, the points falling within and registered, by means of point
//  indices, in the parent node are distributed to the child nodes for delegated
//  maintenance. In fact, only leaf nodes, i.e., those without any descendants,
//  actually store point indices while each node, regardless of a leaf or non-
//  leaf node, keeps a dynamically updated Data Bounding Box of the inhabitant 
//  points, if any. Given a maximum number of points per leaf node, an octree 
//  is initialized with an empty leaf node that is then recursively sub-divided, 
//  but only on demand as points are incrementally inserted, to construct a 
//  populated tree.
//
//  Please note that this octree node class is able to handle a large number
//  of EXACTLY duplicate points that is greater than the specified maximum
//  number of points per leaf node. In other words, as an exception, a leaf
//  node may maintain an arbitrary number of exactly duplicate points to deal
//  with possible extreme cases.
// 
// .SECTION See Also
//  vtkIncrementalOctreePointLocator

#ifndef __vtkIncrementalOctreeNode_h
#define __vtkIncrementalOctreeNode_h

#include "vtkObject.h"

class vtkPoints;
class vtkIdList;

class VTK_FILTERING_EXPORT vtkIncrementalOctreeNode : public vtkObject
{
public:
  vtkTypeMacro( vtkIncrementalOctreeNode, vtkObject );
  void PrintSelf( ostream & os, vtkIndent indent );

  static vtkIncrementalOctreeNode * New();
  
  // Description:
  // Get the number of points inside or under this node.
  vtkGetMacro( NumberOfPoints, int );
  
  // Description:
  // Get the list of point indices, NULL for a non-leaf node.
  vtkGetObjectMacro( PointIdSet, vtkIdList );
  
  // Description:
  // Delete the eight child nodes.
  void DeleteChildNodes();
  
  // Description:
  // Set the spatial bounding box of the node. This function sets a default
  // data bounding box.
  void SetBounds( double x1, double x2, double y1, 
                  double y2, double z1, double z2 );
  
  // Description:
  // Get the spatial bounding box of the node. The values are returned via
  // an array in order of: x_min, x_max, y_min, y_max, z_min, z_max.   
  void GetBounds( double bounds[6] ) const;
                     
  // Description:
  // Get access to MinBounds. Do not free this pointer.
  vtkGetVector3Macro( MinBounds, double );
  
  // Description:
  // Get access to MaxBounds. Do not free this pointer.
  vtkGetVector3Macro( MaxBounds, double );
  
  // Description:
  // Get access to MinDataBounds. Note that MinDataBounds is not valid until
  // point insertion.
  double * GetMinDataBounds()
  { return this->NumberOfPoints ? this->MinDataBounds : this->MinBounds; }
  
  // Description:
  // Get access to MaxDataBounds. Note that MaxDataBounds is not valid until
  // point insertion.
  double * GetMaxDataBounds()
  { return this->NumberOfPoints ? this->MaxDataBounds : this->MaxBounds; }
                    
  // Description:
  // Determine whether or not this node is a leaf.
  int IsLeaf() { return ( this->Children == NULL ) ? 1 : 0; }
  
  // Description:
  // Determine which specific child / octant contains a given point. Note that
  // the point is assumed to be inside this node and no checking is performed 
  // on the inside issue.
  int GetChildIndex( const double point[3] );
  
  // Description:
  // Get quick access to a child of this node. Note that this node is assumed
  // to be a non-leaf one and no checking is performed on the node type.
  vtkIncrementalOctreeNode * GetChild( int i ) { return this->Children[i]; }
  
  // Description:
  // A point is in a node if and only if MinBounds[i] < p[i] <= MaxBounds[i],
  // which allows a node to be divided into eight non-overlapping children.
  int  ContainsPoint( const double pnt[3] );
  
  // Description:
  // A point is in a node, in terms of data, if and only if MinDataBounds[i]
  // <= p[i] <= MaxDataBounds[i].
  int  ContainsPointByData( const double pnt[3] );
  
  // Description:
  // This function is called after a successful point-insertion check and
  // only applies to a leaf node. Prior to a call to this function, the
  // octree should have been retrieved top-down to find the specific leaf
  // node in which this new point (newPt) will be inserted. The actual index
  // of the new point (to be inserted to points) is stored in pntId. Argument
  // ptMode specifies whether the point is not inserted at all but instead only
  // the point index is provided upon 0, the point is inserted via vtkPoints::
  // InsertPoint() upon 1, or it is inserted via vtkPoints::InsertNextPoint()
  // upon 2. For case 0, pntId needs to be specified. For cases 1 and 2, the
  // actual point index is returned via pntId. Note that this function always
  // returns 1 to indicate the success of point insertion.                
  int InsertPoint( vtkPoints * points, const double newPnt[3], 
                   int maxPts, vtkIdType * pntId, int ptMode );
 
  // Description:
  // Given a point inside this node, get the minimum squared distance to all 
  // inner boundaries. An inner boundary is a node's face that is shared by
  // another non-root node. 
  double GetDistance2ToInnerBoundary( const double point[3], 
                                      vtkIncrementalOctreeNode * rootNode );
                                      
  // Description:
  // Compute the minimum squared distance from a point to this node, with all
  // six boundaries considered. The data bounding box is checked if checkData
  // is non-zero. 
  double GetDistance2ToBoundary( const double point[3],
    vtkIncrementalOctreeNode * rootNode, int checkData );
    
  // Description:
  // Compute the minimum squared distance from a point to this node, with all
  // six boundaries considered. The data bounding box is checked if checkData
  // is non-zero. The closest on-boundary point is returned via closest.
  double GetDistance2ToBoundary( const double point[3], double closest[3],
    vtkIncrementalOctreeNode * rootNode, int checkData );
  
  // Description:
  // Export all the indices of the points (contained in or under this node) by
  // inserting them to an allocated vtkIdList via vtkIdList::InsertNextId().
  void ExportAllPointIdsByInsertion( vtkIdList * idList );
  
  // Description:
  // Export all the indices of the points (contained in or under this node) by
  // directly setting them in an allocated vtkIdList object. pntIdx indicates
  // the starting location (in terms of vtkIdList) from which new point indices
  // are added to vtkIdList by vtkIdList::SetId().
  void ExportAllPointIdsByDirectSet( vtkIdType * pntIdx, vtkIdList * idList );

//BTX
protected:

  vtkIncrementalOctreeNode();
  ~vtkIncrementalOctreeNode();

private:

  // Description:
  // Number of points inside or under this node.
  int  NumberOfPoints;
  
  // Description:
  // The minimum coordinate of this node's spatial bounding box.
  double MinBounds[3];

  // Description:
  // The maximum coordinate of this node's spatial bounding box.
  double MaxBounds[3];
  
  // Description:
  // The minimum coordinate of the data bounding box that encompasses the 
  // points inserted, by means of the point index, to this node. Note this
  // information is invalid if no any point has been inserted to this node.
  double MinDataBounds[3];   

  // Description:
  // The maximum coordinate of the data bounding box that encompasses the 
  // points inserted, by means of the point index, to this node. Note this
  // information is invalid if no any point has been inserted to this node.
  double MaxDataBounds[3];
  
  // Description:
  // The list of indices of the points maintained by this LEAF node. It is 
  // NULL if this is a non-leaf node.
  vtkIdList * PointIdSet;
  
  // Description:
  // The parent of this node, NULL for the root node of an octree.
  vtkIncrementalOctreeNode *  Parent;
  
  // Description:
  // A pointer to the eight children of this node.
  vtkIncrementalOctreeNode ** Children;
  
  // Description:
  // Set the parent of this node, NULL for the root node of an octree.
  virtual void SetParent( vtkIncrementalOctreeNode * );
  
  // Description:
  // Set the list of point indices, NULL for a non-leaf node.
  virtual void SetPointIdSet( vtkIdList * );
  
  // Description:
  // Divide this LEAF node into eight child nodes as the number of points
  // maintained by this leaf node has reached the threshold maxPts while 
  // another point newPnt is just going to be inserted to it. The available
  // point-indices pntIds are distributed to the child nodes based on the 
  // point coordinates (available through points). Note that this function 
  // can incur recursive node-division to determine the specific leaf node
  // for accepting the new point (with pntIdx storing the index in points)
  // because the existing maxPts points may fall within only one of the eight
  // child nodes to make a radically imbalanced layout within the node (to
  // be divided). Argument ptMode specifies whether the point is not inserted
  // at all but instead only the point index is provided upon 0, the point is
  // inserted via vtkPoints::InsertPoint() upon 1, or the point is inserted by
  // vtkPoints::InsertNextPoint() upon 2. The returned value of this function
  // indicates whether pntIds needs to be destroyed (1) or just unregistered
  // from this node as it has been attached to another node (0).
  int CreateChildNodes( vtkPoints * points, vtkIdList * pntIds,
    const double newPnt[3], vtkIdType * pntIdx, int maxPts, int ptMode );
    
  // Description:
  // Create a vtkIdList object for storing point indices. Two arguments
  // specifies the initial and growing sizes, respectively, of the object.
  void CreatePointIdSet( int initSize, int growSize );
  
  // Description:
  // Delete the list of point indices.
  void DeletePointIdSet();
  
  // Description:
  // Given a point inserted to either this node (a leaf node) or a descendant
  // leaf (of this node --- when this node is a non-leaf node), update the
  // counter and the data bounding box for this node only.
  void UpdateCounterAndDataBounds( const double point[3] );
  
  // Description:
  // Given a point inserted to either this node (a leaf node) or a descendant
  // leaf (of this node --- when this node is a non-leaf node), update the
  // counter and the data bounding box for this node only. The data bounding box
  // is considered only if updateData is non-zero. The returned value indicates
  // whether (1) or not (0) the data bounding box is actually updated. Note that
  // argument nHits must be 1 unless this node is updated with a number (nHits)
  // of exactly duplicate points as a whole via a single call to this function.
  int UpdateCounterAndDataBounds
    ( const double point[3], int nHits, int updateData );

  // Description:
  // Given a point inserted to either this node (a leaf node) or a descendant
  // leaf (of this node --- when this node is a non-leaf node), update the 
  // counter and the data bounding box recursively bottom-up until a specified 
  // node. The data bounding box is considered only if updateData is non-zero. 
  // The returned value indicates whether (1) or not (0) the data bounding box
  // is actually updated. Note that argument nHits must be 1 unless this node 
  // is updated with a number (nHits) of exactly duplicate points as a whole 
  // via a single call to this function.
  int UpdateCounterAndDataBoundsRecursively( const double point[3], int nHits,
    int updateData, vtkIncrementalOctreeNode * endNode );
    
  // Description:
  // Given a point, determine whether (1) or not (0) it is an exact duplicate
  // of all the points, if any, maintained in this node. In other words, to
  // check if this given point and all existing points, if any, of this node
  // are exactly duplicate with one another.
  int  ContainsDuplicatePointsOnly( const double pnt[3] );
  
  // Description:
  // Given a number (>= threshold) of all exactly duplicate points (accessable
  // via points and pntIds, but with exactly the same 3D coordinate) maintained
  // in this leaf node and a point (absolutely not a duplicate any more, with 
  // pntIdx storing the index in points)) to be inserted to this node, separate
  // all the duplicate points from this new point by means of usually recursive
  // node sub-division such that the former points are inserted to a descendant
  // leaf while the new point is inserted to a sibling of this descendant leaf.
  // Argument ptMode specifies whether the point is not inserted at all but only 
  // the point index is provided upon 0, the point is inserted via vtkPoints::
  // InsertPoint() upon 1, or this point is instead inserted through vtkPoints::
  // InsertNextPoint() upon 2.
  void SeperateExactlyDuplicatePointsFromNewInsertion( vtkPoints * points, 
    vtkIdList * pntIds, const double newPnt[3], 
    vtkIdType * pntIdx, int maxPts, int ptMode );
                   
  // Description:
  // Given a point, obtain the minimum squared distance to the closest point
  // on a boundary of this node. As two options, the outer boundaries may be
  // excluded (by comparing them against those of the root node) from 
  // consideration and the data bounding box may be checked in place of the
  // spatial bounding box.
  double GetDistance2ToBoundary( const double point[3], double closest[3],
    int innerOnly, vtkIncrementalOctreeNode* rootNode, int checkData = 0 );

  vtkIncrementalOctreeNode( const vtkIncrementalOctreeNode & );// Not implemented
  void operator = ( const vtkIncrementalOctreeNode & );        // Not implemented
//ETX
};

// In-lined for performance
inline int vtkIncrementalOctreeNode::GetChildIndex( const double point[3] )
{ 
  // Children[0]->MaxBounds[] is exactly the center point of this node.
  return int( point[0] > this->Children[0]->MaxBounds[0] ) +
    (  ( int( point[1] > this->Children[0]->MaxBounds[1] ) ) << 1  ) +
    (  ( int( point[2] > this->Children[0]->MaxBounds[2] ) ) << 2  );
}

// In-lined for performance 
inline int vtkIncrementalOctreeNode::ContainsPoint( const double pnt[3] )
{
  return (
            ( this->MinBounds[0] < pnt[0] && pnt[0] <= this->MaxBounds[0] &&
              this->MinBounds[1] < pnt[1] && pnt[1] <= this->MaxBounds[1] &&
              this->MinBounds[2] < pnt[2] && pnt[2] <= this->MaxBounds[2]
            ) ? 1 : 0
         );
}

// In-lined for performance 
inline int vtkIncrementalOctreeNode::ContainsPointByData( const double pnt[3] )
{
  return
  (
     ( this->MinDataBounds[0] <= pnt[0] && pnt[0] <= this->MaxDataBounds[0] &&
       this->MinDataBounds[1] <= pnt[1] && pnt[1] <= this->MaxDataBounds[1] &&
       this->MinDataBounds[2] <= pnt[2] && pnt[2] <= this->MaxDataBounds[2]
     ) ? 1 : 0
  );
}

// In-lined for performance
inline int vtkIncrementalOctreeNode::ContainsDuplicatePointsOnly
  ( const double pnt[3] )
{
  return
  (
     ( this->MinDataBounds[0] == pnt[0] && pnt[0] == this->MaxDataBounds[0] &&
       this->MinDataBounds[1] == pnt[1] && pnt[1] == this->MaxDataBounds[1] &&
       this->MinDataBounds[2] == pnt[2] && pnt[2] == this->MaxDataBounds[2]
     ) ? 1 : 0
  );  
}

// In-lined for performance
inline void vtkIncrementalOctreeNode::UpdateCounterAndDataBounds
  ( const double point[3] )
{
  this->NumberOfPoints ++;
  
  this->MinDataBounds[0] = ( point[0] < this->MinDataBounds[0] ) 
                           ? point[0] : this->MinDataBounds[0];
  this->MinDataBounds[1] = ( point[1] < this->MinDataBounds[1] ) 
                           ? point[1] : this->MinDataBounds[1];
  this->MinDataBounds[2] = ( point[2] < this->MinDataBounds[2] ) 
                           ? point[2] : this->MinDataBounds[2];
  this->MaxDataBounds[0] = ( point[0] > this->MaxDataBounds[0] ) 
                           ? point[0] : this->MaxDataBounds[0];
  this->MaxDataBounds[1] = ( point[1] > this->MaxDataBounds[1] ) 
                           ? point[1] : this->MaxDataBounds[1];
  this->MaxDataBounds[2] = ( point[2] > this->MaxDataBounds[2] ) 
                           ? point[2] : this->MaxDataBounds[2];
}

// In-lined for performance 
inline int vtkIncrementalOctreeNode::UpdateCounterAndDataBoundsRecursively
  ( const double point[3], int nHits, int updateData, 
    vtkIncrementalOctreeNode * endNode )
{
  int  updated = this->UpdateCounterAndDataBounds
                       ( point, nHits, updateData );
  
  return (    ( this->Parent == endNode )
           ?  updated 
           :  this->Parent->UpdateCounterAndDataBoundsRecursively
                            ( point, nHits, updated, endNode ) 
         );
}
#endif
